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A wavelength-multiplexing optical communication module includes: a
substrate; a plurality of light sources on the substrate; a plurality of
joint materials separately disposed on the substrate at positions
respectively corresponding to the plurality of light sources; and a
plurality of optical components fixed on the substrate by means of the
plurality of joint materials respectively, wherein the substrate includes
a plurality of forming portions which respectively form peripheries of
the plurality of joint materials into shapes of circles or regular
polygons having an even number of vertices.

1. A wavelength-multiplexing optical communication module comprising: a substrate; a plurality of light sources on the substrate; a plurality of joint materials
separately disposed on the substrate at positions respectively corresponding to the plurality of light sources; and a plurality of optical components fixed on the substrate by means of the plurality of joint materials respectively, wherein the substrate
includes a plurality of forming portions, the plurality of said forming portions including recesses, which recesses respectively form peripheries of the plurality of joint materials into shapes of circles or regular polygons having an even number of
vertices, the joint materials being disposed only within the recesses, and light-receiving regions of the plurality of optical components are not covered by the plurality of joint materials.

2. The wavelength-multiplexing optical communication module of claim 1, wherein the plurality of forming portions include recesses formed on the substrate and the joint materials fill the recesses.

3. The wavelength-multiplexing optical communication module of claim 1, wherein the plurality of forming portions include joint material application regions where the joint materials are applied and organic films provided on peripheries of the
joint material application regions.

4. The wavelength-multiplexing optical communication module of claim 1, wherein the plurality of forming portions include joint material application regions where the joint materials are applied and joint material non-application regions
provided on peripheries of the joint material application regions.

5. The wavelength-multiplexing optical communication module of claim 4, wherein the joint materials are resin adhesives, the joint material application regions are formed of a same polymer material as the resin adhesives or a metallic member
processed so as to be made hydrophilic, and the joint material non-application regions are formed of a fat or oil material or a metallic member processed so as to be water-repellant.

6. The wavelength-multiplexing optical communication module of claim 4, wherein the joint materials are solder, the joint material application regions are formed of a metallic member processed so as to be made hydrophilic, and the joint
material non-application regions are formed of a fat or oil material or a metallic member processed so as to be water-repellant.

7. A wavelength-multiplexing optical communication module comprising: a substrate; a plurality of light sources on the substrate; a plurality of joint materials separately disposed on the substrate at positions respectively corresponding to
the plurality of light sources; and a plurality of optical components fixed on the substrate by means of the plurality of joint materials respectively, wherein the substrate includes a plurality of forming portions, the plurality of said forming
portions including recesses, which recesses respectively form peripheries of the plurality of joint materials into shapes of circles or regular polygons having an even number of vertices, the joint materials being disposed only within the recesses, and
said optical components comprise at least a plurality of wavelength selecting filters, a single optical coupler, and a single mirror, such that each of the plurality of wavelength selecting filters corresponds to a respective light source of the
plurality of light sources.

9. The wavelength-multiplexing optical communication module of claim 1, wherein output beams of the plurality of light sources are made incident on side surfaces of the plurality of optical components respectively.

Description

BACKGROUND OF THE INVENTION

Field

This invention relates to a wavelength-multiplexing optical communication module which performs communication by wavelength-multiplexing a plurality of optical signals differing in wavelength.

Background

A wavelength-multiplexing optical communication module transmits, by using optical components such as optical lenses, wavelength selecting filters and a reflecting mirror, signal lights emitted from a plurality of light sources. The optical
lenses are fixed on a substrate with a joint material. The arrangement for wavelength-multiplexing the lights emitted from the plurality of light sources and outputting the multiplexed light to an external optical transmission path requires fixing the
optical lenses with high position accuracy.

A conventional wavelength-multiplexing optical communication module is known which has grooves in lattice form provided around each of portions on which optical lenses are mounted to prevent interference between pieces of a resin adhesive for
fixing the optical lenses (see, for example, JP 2014-102498, hereinafter Patent Literature 1).

In the wavelength-multiplexing optical communication module described in Patent Literature 1, however, the peripheral shapes of pieces of the resin adhesive applied cannot be uniformly formed and there is, therefore, a possibility of the shape
of each piece of the resin adhesive being asymmetric with respect to the position of the optical lens disposed on the optical path. In such a case, because stress acting on the optical lens is asymmetric when the resin adhesive cures and shrinks, a
misalignment of the optical lens occurs during curing of the resin adhesive and the optical lens cannot be fixed with high positional accuracy.

SUMMARY

In view of the above-described problem, an object of this invention is to obtain a wavelength-multiplexing optical communication module capable of inhibiting a misalignment of an optical component due to curing shrinkage of a joint material arid
fixing the optical component with high positional accuracy.

According to the present invention, a wavelength-multiplexing optical communication module includes: a substrate; a plurality of tight sources on the substrate; a plurality of joint materials separately disposed on the substrate at positions
respectively corresponding to the plurality of light sources; and a plurality of optical components fixed on the substrate by means of the plurality of joint materials respectively, wherein the substrate includes a plurality of forming portions which
respectively form peripheries of the plurality of joint materials into shapes of circles or regular polygons having an even number of vertices.

In the invention, the peripheries of joint materials disposed on a substrate separately one from another are each formed into the shape of a circle or a regular polygon having an even number of vertices. Thus, stress acting on each optical
component when the joint material cures and shrinks is symmetric. As a result, a misalignment of the optical component due to curing shrinkage of the joint material is inhibited and the optical component can be fixed with high positional accuracy.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a diagram schematically showing the wavelength-multiplexing optical communication module according to the first embodiment of the present invention.

FIG. 2 is a top view showing the substrate according to the first embodiment of the present invention.

FIG. 3 is an enlarged sectional view showing the substrate according to the first embodiment of the present invention.

FIG. 4 is an enlarged sectional view showing a major part of the wavelength-multiplexing optical communication module according to the first embodiment of the present invention.

FIG. 5 is a perspective view of the optical lens according to the first embodiment of the present invention.

FIG. 6 is an enlarged sectional view showing the substrate according to the second embodiment of the present invention.

FIG. 7 is an enlarged sectional view showing the substrate according to the third embodiment of the present invention.

DESCRIPTION OF EMBODIMENTS

First Embodiment

A wavelength-multiplexing optical communication module according to a first embodiment of this invention will be described. FIG. 1 is a diagram schematically showing the wavelength-multiplexing optical communication module according to the
first embodiment.

The construction of a wavelength-multiplexing optical communication module according to the first embodiment will first be described. The wavelength-multiplexing optical communication module 1 is constituted by a main body 2 and a receptacle 3. The main body 2 has a package 4 in which a Peltier element (not shown) is fixed with solder. A substrate 5 is fixed on an upper surface of the Peltier element with solder, and light sources 6a to 6d are fixed on an upper surface of the substrate 5 with
solder. The light sources 6a to 6d are connected to a feed-through part 12 by gold wires (not shown) and are driven from the outside through the feed-through part 12.

FIG. 2 is a top view of the substrate 5. FIG. 3 is a sectional view taken along line A-A in FIG. 2, showing a state after application of a piece of resin adhesive 8a on the substrate 5. FIG. 4 is a sectional view taken along line B-B in FIG.
1. Recesses 5a-1 to 5a-4 in the shape of a circle are separately disposed in a row on the substrate 5 at positions respectively corresponding to the light sources 6a to 6d. The recesses 5a-1 to 5a-4 are formed by drilling or etching. For example, the
recesses 5a-1 to 5a-4 have a diameter D1 of 0.65 to 1.95 mm, a depth D2 of 0.05 to 0.2 mm, and a center-to-center distance D3 of 0.7 to 2.0 mm between each adjacent pair of the recesses. However, it is necessary that the center-to-center distance D3 he
larger by about 0.05 mm or more than the diameter D1, since the recesses 5a-1 to 5a-4 are disposed separately one from another. More specifically, for example, the diameter D1 is 1.5 mm, the depth D2 is 0.2 mm, and the center-to-center distance D3 is
1.7 mm.

Optical lenses 7a to 7d, which are optical components, are fixed on the substrate 5 by means of a joint material, and an ultraviolet curing type of resin adhesive is used as the joint material. Pieces of resin adhesive 8a to 8d fill the
recesses 5a-1 to 5a-4, respectively. The pieces of resin adhesive 8a to 8d have a thickness T of, for example, 0.02 to 0.2 mm, more specifically 0.05 mm. The recesses 5a-1 to 5a-4 are forming portions which form the peripheries of the pieces of resin
adhesive 8a to 8d, and which are formed so that the optical lenses 7a to 7d are at about centers of the recesses 5a-1 to 5a-4 when the optical lenses 7a to 7d are respectively disposed on optical axis for lights emitted from light sources 6a to 6d.

FIG. 5 is a perspective view of the optical lens 7a. For example, the optical lens 7a has a height HL of 0.6 to 1.5 mm, a width WL is 0.38 to 1.3 mm, and a depth DL of 0.38 to 1.3 mm. Setting the optical lens 7a in the recess 5a-1 requires
providing a gap of 0.05 mm or more between a wall portion of the recess 5a-1 and the optical lens 7a. More specifically, for example, the height HL is 1.3 mm, the width WL is 0.9 mm, and the depth DL is 0.9 mm. The optical lenses 7a to 7d are identical
in shape to each other.

A lid (not shown) is welded to the package 4 to hermetically enclose the interior of the package 4. An optical coupler 9 is fixed in the package 4 with a resin adhesive. Wavelength selecting filters 10a to 10d and a reflecting mirror 11 are
provided in the optical coupler 9. A window 13 with seal glass is provided on the package 4. A receptacle 3 is fixed on the package 4 at a position at which signal light passing through the window 13 is output to an external optical transmission path.

The operation of the wavelength-multiplexing optical communication module according to the first embodiment will subsequently be described. The light sources 6a to 6d are supplied with electrical signals externally and output optical signals of
wavelengths .lamda.a to .lamda.d different from each other. The optical lenses 7a to 7d respectively adjust the wavefronts of lights emitted from the light sources 6a to 6d and convert the lights into collimated lights.

The wavelength selecting filter 10a has such a characteristic as to transmit light of wavelength .lamda.a while reflecting lights of wavelengths .lamda.b, .lamda.c and .lamda.d. Light of wavelength .lamda.a exiting from the optical lens 7a is
passed through the wavelength selecting filter 10a to be emitted to the window 13.

The wavelength selecting filter 10b has such a characteristic as to transmit light of wavelength .lamda.b while reflecting lights of wavelengths .lamda.c and .lamda.d. Light of wavelength .lamda.b exiting from the optical lens 7b is passed
through the wavelength selecting filter 10b and is reflected successively by the reflecting mirror 11 and by the wavelength selecting filter 10a to be emitted to the window 13.

The wavelength selecting filter 10c has such a characteristic as to transmit light of wavelength .lamda.c while reflecting light of wavelength .lamda.d. Light of wavelength .lamda.c exiting from the optical lens 7c is passed through the
wavelength selecting filter 10c and is reflected successively by the reflecting mirror 11, by the wavelength selecting filter 10b, by the reflecting mirror 11 and by the wavelength selecting filler 10a to be emitted to the window 13.

The wavelength selecting filter 10d has such a characteristic as to transmit light of wavelength .lamda.d. Light of wavelength .lamda.d exiting from the optical lens 7d is passed through the wavelength selecting filter 10d and is reflected
successively by the reflecting mirror 11, by the wavelength selecting filter 10c, by the reflecting mirror 11, by the wavelength selecting filter 10b, by the reflecting mirror 11 and by the wavelength selecting filter 10a to be emitted to the window 13.

The lights with the wavelengths .lamda.a to .lamda.d thus emitted to the window 13 are passed through the window 13, wavelength-multiplexed and emitted to the receptacle 3. The wavelength-multiplexed light is output to the external optical
transmission path through the receptacle 3. The paths through which the lights emitted from the light sources 6a to 6d travel are as indicated by the dotted lines in FIG. 1.

A process of manufacturing the wavelength-multiplexing optical communication module according to the first embodiment will subsequently be described. The Peltier element is first fixed in the package 4 with solder. The substrate 5 is fixed on
the upper surface of the Peltier element with solder. The light sources 6a to 6d are thereafter fixed on the upper surface of the substrate 5 with solder.

Subsequently, an ultraviolet curing type of resin adhesive is applied to the package 4, the optical coupler 9 is placed on the resin adhesive, and the resin adhesive is cured by being irradiated with ultraviolet rays, thereby fixing the optical
coupler 9 in the package 4.

Subsequently, a piece of the ultraviolet curing type of resin adhesive 8a is applied so as to fill the recess 5a-1. At this time, the periphery of the piece of resin adhesive 8a applied is formed into the shape of a circle since the recess 5a-1
has the shape of a circle. The optical lens 7a is disposed at about the center of the piece of resin adhesive 8a, the light source 6a is thereafter caused to emit light, and the position of the optical lens 7a is adjusted so that the quantity of light
received by a monitoring device set outside the window 13 is maximized. After the completion of the position adjustment, the piece of resin adhesive 8a is cured by being irradiated with ultraviolet rays. The optical lens 7a is thereby fixed on the
substrate 5.

The optical lenses 7b to 7d are fixed in recesses 5a-2 to 5a-4 on the substrate 5 in the same way as the optical lens 7a.

Each of the peripheries of the pieces of resin adhesive 8a to 8d is formed into the shape of a circle, as described above. In the shape of the circle, all points on the circumference have the same distance from the center. Therefore, if the
shapes of the peripheries of the pieces of resin adhesive 8a to 8d are circular, each of stresses which act on the pieces of resin adhesive 8a to 8d during curing shrinkage of the resin adhesive is generated symmetrically about the center of the circle.
Thus, misalignments with respect to the adjusted positions of the optical lenses 7a to 7d respectively placed on the pieces of resin adhesive 8a to 8d are inhibited.

The lid is welded to the package 4 in a nitrogen atmosphere to hermetically enclose the interior of the package 4. Finally, the receptacle 3 is fixed on the package 4, thereby completing the wavelength-multiplexing optical communication module
1.

The above-described manufacturing process and sequence of manufacturing steps are only an example, and the invention is not limited to the above-described details.

In the first embodiment, the peripheries of the pieces of resin adhesive 8a to 8d are formed into the shapes of circles with the forming portions constituted by the recesses 5a-1 to 5a-4 filled with the pieces of resin adhesive 8a to 8d as a
joint material and each having the shape of a circle. Therefore, each of stresses which act on the optical lenses 7a to 7d placed at about the centers of a pieces of resin adhesive 8a to 8d during curing shrinkage of the resin adhesive is symmetric
about the center of the circle, thereby inhibiting misalignments of the optical lenses 7a to 7d caused by curing shrinkage of the resin adhesive. Consequently, the optical lenses 7a to 7d can be fixed with high positional accuracy.

Also, the pieces of resin adhesive 8a to 8d filling the recesses 5a-1 to 5a-4 do not interfere with each other since the recesses 5a-1 to 5a-4 are disposed separately one from another. The plurality of optical lenses 7a to 7d can therefore he
fixed with high positional accuracy.

Second Embodiment

A wavelength-multiplexing optical communication module according to a second embodiment of this invention will be described. The difference between the wavelength-multiplexing optical communication module according to the second embodiment and
the wavelength-multiplexing optical communication module according to the first embodiment resides in the substrate. In other respects, the arrangement according to the second embodiment is the same as that according to the first embodiment. FIG. 6 is
a sectional view showing a state after application of a piece of resin adhesive 8a on a substrate 51 in the wavelength-multiplexing optical communication module according to the second embodiment. The position of the section is the same as that of FIG.
3. The substrate 51 is constituted by a base member 51d and an organic film 51e of a solder resist formed on the base member 51d. When the organic film 51e is formed, joint material application regions 51f-1 to 51f-4, which are regions where pieces of
resin adhesive 8a to 8d for fixing the optical lenses 7a to 7d are applied, are masked. Accordingly, the organic film 51e is formed so that the joint material application regions 51f-1 to 51f-4 are left empty. The joint material application regions
51f-1 to 51f-4 each have the shape of a circle and are disposed in a row separately one from another.

The pieces of resin adhesive 8a to 8d are applied so as to fill the joint material application regions 51f-1 to 51f-4, respectively. Wetting and spreading of the pieces of resin adhesive 8a to 8d stop at the organic film 51e. Therefore, the
shapes of the peripheries of the pieces of resin adhesives 8a to 8d are respectively determined by the shapes of the joint material application regions 51f-1 to 51f-4. That is, the joint material application regions 51f-1 to 51f-4 and the organic film
51e constitute forming portions which form the peripheries of the pieces of resin adhesive 8a to 3d.

In the second embodiment, the peripheries of the pieces of resin adhesive 8a to 8d are formed into the shapes of circles with the forming portions constituted by the joint material application regions 51f-1 to 51f-4 filled with the pieces of
resin adhesive 8a to 3d as a joint material and each having the shape of a circle and the organic film 51e. Therefore, each of stresses which act on the optical lenses 7a to 7d placed at about the centers of the pieces of resin adhesive 8a to 8d during
curing shrinkage of the resin adhesive is symmetric about the center of the circle, as is that in the first embodiment. Misalignments of the optical lenses 7a to 7d caused by curing shrinkage of the resin adhesive are inhibited thereby. Consequently,
the optical lenses 7a to 7d can be fixed with high positional accuracy.

Also, as in the case of the first embodiment, the pieces of resin adhesive 8a to 8d do not interfere with each other since the joint material application regions 51f-1 to 51f-4 are disposed separately one from another. The plurality of optical
lenses 7a to 7d can therefore be fixed with high positional accuracy.

Third Embodiment

A wavelength-multiplexing optical communication module according to a third embodiment of this invention will be described. The difference between the wavelength-multiplexing optical communication module according to the third embodiment and
the wavelength-multiplexing optical communication module according to the first embodiment resides in the substrate. In other respects, the arrangement according to the third embodiment is the same as that according to the first embodiment. FIG. 7 is a
sectional view showing a state after application of a piece of resin adhesive 8a on a substrate 52 in the wavelength-multiplexing optical communication module according to the third embodiment. The position of the section is the same as that of FIG. 3.
Joint material application regions 52f-1 to 52f-4, which are regions where pieces of resin adhesive 8a to 8d are applied, and joint material non-application regions 52g provided on the peripheries of the joint material application regions 52f-1 to 52f-4
are formed on an upper portion of a base member 52d. The substrate 52 is constituted by the base member 52d, the joint material application regions 52f-1 to 52f-4 and the joint material non-application regions 52g. The joint material application
regions 52f-1 to 52f-4 are formed of the same polymer material as the pieces of resin adhesive 8a to 8d, and the joint material non-application regions 52g are formed of a fat or oil material. Therefore the wettability of the joint material
non-application regions 52g to the resin adhesive is lower than that of the joint material application regions 52f-1 to 52f-4. The joint material application regions 52f-1 to 52f-4 each have the shape of a circle and are disposed in a row separately one
from another.

The pieces of resin adhesive 8a to 8d are applied so as to fill the joint material application regions 52f-1 to 52f-4, respectively. Wetting and spreading of the pieces of resin adhesive 8a to 8d stop at the joint material non-application
regions 52g having lower wettability to the resin adhesive. Therefore, the shapes of the peripheries of the pieces of resin adhesives 8a to 8d are respectively determined by the shapes of the joint material application regions 52f-1 to 52f-4. That is,
the joint material application regions 52f-1 to 52f-4 and the joint material non-application regions 52g constitute forming portions which form the peripheries of the pieces of resin adhesive 8a to 8d.

In the third embodiment, the peripheries of the pieces of resin adhesive 8a to 8d are formed into the shapes of circles with the forming portions constituted by the joint material application regions 52f-1 to 52f-4 filled with the pieces of
resin adhesive 8a to 8d as a joint material and each having the shape of a circle and the joint material non-application regions 52g. Therefore, each of stresses which act on the optical lenses 7a to 7d placed at about the centers of the pieces of resin
adhesive 8a to 8d during curing shrinkage of the resin adhesive is symmetric about the center of the circle, as is that in the first embodiment. Misalignments of the optical lenses 7a to 7d are inhibited thereby. Consequently, the optical lenses 7a to
7d can be fixed with high positional accuracy.

Also, as in the case of the first embodiment, the pieces of resin adhesive 8a to 8d do not interfere with each other since the joint material application regions 52f-1 to 52f-4 are disposed separately one from another. The plurality of optical
lenses 7a to 7d can therefore be fixed with high positional accuracy.

The description has been made by assuming that each of recesses 5a-1 to 5a-4 in the first embodiment, the joint material application regions 51f-1 to 51f-4 in the second embodiment and the joint material application regions 52f-i to 52f-4 in the
third embodiment has the shape of a circle. However, the optical lenses 7a to 7d can also be fixed with high positional accuracy when each of the recesses or the regions has the shape of a regular polygon having an even number of vertices. This is
because a regular polygon having an even number of vertices is a shape having a point symmetry about its center, and because, if the joint material has such a shape, stresses applied to two points at point symmetrical positions about the center of the
joint material during curing shrinkage of the joint material are generated symmetrically about the center of the joint material such that misalignments with respect to the adjusted positions of the optical lenses 7a to 7d respectively disposed on the
joint materials are inhibited.

While the first to third embodiments have been described with respect to a case where an ultraviolet curing type of resin adhesive is used as a joint material for fixing optical lenses, a heat curing type of resin adhesive or solder may
alternatively be used.

While the first to third embodiments have been described with respect to a case where optical lenses are used as optical components, wavelength selecting filters or reflecting mirrors may alternatively be used.

While the optical lenses are placed after the resin adhesive is applied on the substrate in the first to third embodiments, the process may alternatively be such that the resin adhesive is applied on the bottom surface of each optical lens in
advance and the optical lens is thereafter placed on the substrate.

While the third embodiment has been described with respect to a case where the same polymer material as the pieces of resin adhesive 8a to 8d is used as a material forming the joint material application regions 52f-1 to 52f-4, a metallic member
processed so as to be made hydrophilic may alternatively be used. Also, while the embodiment has been described with respect to a case where a fat or oil material is used as a material forming the joint material non-application region 52g, a metallic
member processed so as to be water-repellant may alternatively be used.

Obviously many modifications and variations of the present invention are possible in the light of the above teachings. It is therefore to be understood that within the scope of the appended claims the invention may be practiced otherwise than
as specifically described.

The entire disclosure of Japanese Patent Application No. 2015-210486 filed on Oct. 27, 2015 including specification, claims, drawings and summary, on which the Convention priority of the present application is based, is incorporated herein by
reference in its entirety.